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What are the laws of physics?
Resisting reification
Carlton M. Caves
C. M. Caves, C. A. Fuchs, and R. Schack, “Subjective probability and quantum certainty,”
Studies in History and Philosophy of Modern Physics 38, 255-274 (2007).
C. G. Timpson, “Quantum Bayesianism: A Study,” Studies in History and Philosophy of
Modern Physics 39, 579-609 (2008).
Department of Physics and Astronomy
University of New Mexico
[email protected]
http://info.phys.unm.edu/~caves
The laws are out there. Probabilities aren’t.
Laws of physics?
Some mathematical objects in a scientific theory are our
tools; others correspond to reality. Which is which?
Subjective Bayesian probabilities
Oljeto Wash
Southern Utah
Objective probabilities
● Probabilities as frequencies: probability as verifiable fact
■ Probabilities are used routinely for individual systems.
■ Frequencies are observed facts, not probabilities.
■ Bigger sample space: exchangeability.
QM: Derivation of quantum
probability rule from
infinite frequencies?
C. M. Caves, R. Schack, ``Properties of the frequency
operator do not imply the quantum probability
postulate,'' Annals of Physics 315, 123-146 (2005)
[Corrigendum: 321, 504--505 (2006)].
● Objective chance (propensity): probability as specified fact
■ Some probabilities are ignorance probabilities, but others are
specified by the facts of a “chance situation.”
■ Specification of “chance situation”: same, but different.
chance
objective
QM: Probabilities from physical law.
Salvation of objective chance?
● Logical probabilities (objective Bayesian): physical symmetry
implies probability
■ Symmetries are applied to judgments, not to facts.
Subjective Bayesian probabilities
Category distinction
Facts
Probabilities
Outcomes of events
Truth values of propositions
Agent’s degree of belief
in outcome of an event or
truth of a proposition
Objective
Subjective
Facts never imply (nontrivial) probabilities.
Two agents in possession of the same facts
can assign different probabilities.
Subjective Bayesian probabilities
Probabilities
Agent’s degree of belief in outcome of an
event or truth of a proposition.
Consequence of ignorance
Agent’s betting odds
Subjective
Agent A regards $q as
fair price for the ticket.
A assigns p(E)=q.
Dutch-book consistency
A’s probability assignments, i.e., ticket prices,
are inconsistent if they can lead to a sure loss.
The standard rules for manipulating
probabilities are objective consequences of
requiring consistent betting behavior.
The usual argument: If A does not obey the
probability rules, she will lose in the long run.
Dutch-book argument: If A does not obey the
probability rules, she will lose in one shot.
Dutch-book argument: Rules (i) and (ii)
A is willing to sell ticket for a negative amount.
Sure loss.
A is willing to sell ticket, which is definitely worth $1
to her, for less than $1.
Sure loss.
Dutch-book argument: Rule (iii)
A would buy the purple ticket for $q and sell the
green tickets for $r + $s.
If q > r + s, sure loss.
Dutch-book argument: Rule (iv)
Subjective Bayesian probabilities
The standard rules of probability
theory are objective
consequences of requiring
consistent betting behavior.
Subjective Bayesian probabilities
Facts in the form of observed data d are used
to update probabilities via Bayes’s rule:
conditional (model, likelihood)
prior
posterior
The posterior always depends on the prior,
except when d logically implies h0:
Facts never determine (nontrivial) probabilities.
Are quantum probabilities subjective?
Bungle Bungle Range
Western Australia
Classical (realistic,
deterministic) world
Quantum world
State space
Simplex of probabilities for
microstates
Convex set of density operators
State
Extreme point
Microstate
Extreme point
Pure state
State vector
Ensemble
Ensemble
Mixed state
Density operator
Scorecard:
1. Predictions for fine-grained measurements
2. Verification (state determination)
3. State change on measurement
4. Uniqueness of ensembles
5. Nonlocal state change (steering)
6. Specification (state preparation)
Objective
Subjective
Objective
Subjective
Classical (realistic,
deterministic) world
Quantum world
State space
Simplex of probabilities for
microstates
Convex set of density operators
State
Extreme point
Microstate
Ensemble
Extreme point
Pure state
State vector
Ensemble
Mixed state
Density operator
Certainty
Probabilities
Certainty or
Probabilities
Probabilities
Fine-grained
measurement
Certainty:
Objective
Subjective
Objective
Subjective
Classical (realistic,
deterministic) world
Quantum world
State space
Simplex of probabilities for
microstates
Convex set of density operators
State
Extreme point
Microstate
Ensemble
Extreme point
Pure state
State vector
Ensemble
Mixed state
Density operator
Yes
No
No
No
Verification:
state determination
Whom do you ask for the system
state? The system or an agent?
Classical (realistic,
deterministic) world
Quantum world
State space
Simplex of probabilities for
microstates
Convex set of density operators
State
Extreme point
Microstate
Extreme point
Pure state
State vector
Ensemble
Ensemble
Mixed state
Density operator
Can you reliably distinguish two nonidentical states?
iff orthogonal
Always
iff orthogonal
iff orthogonal
iff orthogonal
Classical (realistic,
deterministic) world
Quantum world
State space
Simplex of probabilities for
microstates
Convex set of density operators
State
Extreme point
Microstate
Extreme point
Pure state
State vector
Ensemble
Ensemble
Mixed state
Density operator
Can you unambiguously distinguish two nonidentical states?
Sometimes
(iff supports
not identical)
Always
Always
(supports are not
identical)
Sometimes
(iff supports not
identical)
Classical (realistic,
deterministic) world
Quantum world
State space
Simplex of probabilities for
microstates
Convex set of density operators
State
Extreme point
Microstate
Ensemble
Extreme point
Pure state
State vector
Ensemble
Mixed state
Density operator
Yes
No
No
No
Verification:
state determination
Whom do you ask for the system
state? The system or an agent?
Objective
Subjective
Objective
Subjective
Classical (realistic,
deterministic) world
Quantum world
State space
Simplex of probabilities for
microstates
Convex set of density operators
State
Extreme point
Microstate
Ensemble
Extreme point
Pure state
State vector
Ensemble
Mixed state
Density operator
No
Yes
Yes
Yes
State change on
measurement
State-vector reduction
or wave-function collapse
Real physical disturbance?
Objective
Subjective
Subjective
Subjective
Classical (realistic,
deterministic) world
Quantum world
State space
Simplex of probabilities for
microstates
Convex set of density operators
State
Extreme point
Microstate
Ensemble
Extreme point
Pure state
State vector
Ensemble
Mixed state
Density operator
Yes
No
No
No
Objective
Subjective
Subjective
Subjective
Uniqueness of
ensembles
Classical (realistic,
deterministic) world
Quantum world
State space
Simplex of probabilities for
microstates
Convex set of density operators
State
Extreme point
Microstate
Ensemble
Extreme point
Pure state
State vector
Ensemble
Mixed state
Density operator
No
Yes
Yes
Yes
Nonlocal state
change (steering)
Real nonlocal physical
disturbance?
Objective
Subjective
Subjective
Subjective
Classical (realistic,
deterministic) world
Quantum world
State space
Simplex of probabilities for
microstates
Convex set of density operators
State
Extreme point
Microstate
Ensemble
Extreme point
Pure state
State vector
Ensemble
Mixed state
Density operator
Certainty
Probabilities
Certainty or
Probabilities
Probabilities
Verification:
state determination
Yes
No
No
No
State change on
measurement
No
Yes
Yes
Yes
Uniqueness of
ensembles
Yes
No
No
No
Nonlocal state
change (steering)
No
Yes
Yes
Yes
Specification:
state preparation
Yes
No
?
?
Objective
Subjective
Subjective
Subjective
Fine-grained
measurement
Copenhagen vs. Bayes
Truchas from East Pecos Baldy
Sangre de Cristo Range
Northern New Mexico
Classical (realistic,
deterministic) world
Quantum world
State space
Simplex of probabilities for
microstates
Convex set of density operators
State
Extreme point
Microstate
Ensemble
Extreme point
Pure state
State vector
Ensemble
Mixed state
Density operator
Yes
No
Copenhagen: Yes
Copenhagen: Yes
Specification:
state preparation
Copenhagen interpretation:
Classical facts specifying
the properties of the
preparation device
determine a pure state.
Objective
Copenhagen (objective
preparations view) becomes
the home of objective chance,
with nonlocal physical
disturbances.
Subjective
Objective
Objective
Classical (realistic,
deterministic) world
Quantum world
State space
Simplex of probabilities for
microstates
Convex set of density operators
State
Extreme point
Microstate
Ensemble
Extreme point
Pure state
State vector
Ensemble
Mixed state
Density operator
Certainty
Probabilities
Certainty or
Probabilities
Probabilities
Verification:
state determination
Yes
No
No
No
State change on
measurement
No
Yes
Yes
Yes
Uniqueness of
ensembles
Yes
No
No
No
Nonlocal state
change (steering)
No
Yes
Yes
Yes
Specification:
state preparation
Yes
No
Yes
Yes
Objective
Subjective
Objective
Objective
Copenhagen
Fine-grained
measurement
Classical and quantum updating
Facts in the form of observed
data d are used to update
probabilities via Bayes’s rule:
Facts in the form of observed
data d are used to update
quantum states:
quantum operation (model)
conditional (model, likelihood)
prior
prior
posterior
posterior
The posterior always depends
on the prior, except when d
logically implies h0:
Quantum state preparation:
The posterior state always depends on
prior beliefs, even for quantum state
preparation, because there is a
judgment involved in choosing the
quantum operation.
Facts never determine probabilities
or quantum states.
Where does Copenhagen go wrong?
The Copenhagen interpretation forgets that the
preparation device is quantum mechanical. A detailed
description of the operation of a preparation device
(provably) involves prior judgments in the form of
quantum state assignments.
It is possible to show that neither deterministic
nor stochastic preparation devices can
prepare the same system state independent of
system and device initial states.
Subjective
Bayesian
Classical (realistic,
deterministic) world
Quantum world
State space
Simplex of probabilities for
microstates
Convex set of density operators
State
Extreme point
Microstate
Ensemble
Extreme point
Pure state
State vector
Ensemble
Mixed state
Density operator
Certainty
Probabilities
Certainty or
Probabilities
Probabilities
Verification:
state determination
Yes
No
No
No
State change on
measurement
No
Yes
Yes
Yes
Uniqueness of
ensembles
Yes
No
No
No
Nonlocal state
change (steering)
No
Yes
Yes
Yes
Specification:
state preparation
Yes
No
No
No
Objective
Subjective
Subjective
Subjective
Fine-grained
measurement
Bayesian quantum probabilities
Echidna Gorge
Bungle Bungle Range
Western Australia
Quantum states vs. probabilities
Are quantum states the same as
probabilities? No, though both are subjective,
there are differences, but these differences
should be stated in Bayesian terms.
A quantum state is a catalogue of
probabilities, but the rules for manipulating
quantum states are different than for
manipulating probabilities.
The rules for manipulating quantum states are
objective consequences of restrictions on how
agents interface with the real world.
Catalogue of probabilities: Fuchs’s gold standard
Symmetric Informationally Complete (SIC)-POVM
Quantum coin tossing
Cable Beach
Western Australia
Is a quantum coin toss more random than a classical one?
Why trust a quantum random generator over a classical one?
Measure spin along z axis:
Measure spin along x axis:
C. M. Caves, R. Schack, “Quantum randomness,” in preparation.
quantum coin toss
Classical (realistic,
deterministic) world
Quantum world
State space
Simplex of probabilities for
microstates
Convex set of density operators
State
Extreme point
Microstate
Ensemble
Extreme point
Pure state
State vector
Ensemble
Mixed state
Density operator
Certainty
Probabilities
Certainty or
Probabilities
Probabilities
Fine-grained
measurement
Is a quantum coin toss more random than a classical one?
Why trust a quantum random generator over a classical one?
Measure spin along z axis:
Measure spin along x axis:
quantum coin toss
Standard answer: The quantum coin toss is objective, with
probabilities guaranteed by physical law.
Subjective Bayesian answer? No inside information.
Pure states and inside information
Party B has inside information about event E, relative to party A,
if A is willing to agree to a bet on E that B believes to be a sure
win. B has one-way inside information if B has inside
information relative to A, but A does not have any inside
information relative to A.
The unique situation in which no other party can have one-way
inside information relative to a party Z is when Z assigns a pure
state. Z is said to have a maximal belief structure.
Subjective Bayesian answer
We trust quantum over classical coin tossing because
an agent who believes the coin is fair cannot rule
out an insider attack, whereas the beliefs that lead
to a pure-state assignment are inconsistent with any
other party’s being able to launch an insider attack.
A stab at ontology
Cape Hauy
Tasman Peninsula
A stab at ontology
Quantum systems are defined by attributes, such as
position, momentum, angular momentum, and energy or
Hamiltonian. These attributes—and thus the numerical
particulars of their eigenvalues and eigenfunctions—are
objective properties of the system.
The value assumed by an attribute is not an
objective property, and the quantum state that we
use to describe the system is purely subjective.
A stab at ontology
1. The attributes orient and give structure to a system’s Hilbert
space. Without them we are clueless as to how to manipulate
and interact with a system.
2. The attributes are unchanging properties of a system, which
can be determined from observable facts. The attributes
determine the structure of the world.
3. The system Hamiltonian is one of the attributes, playing the
special role of orienting a system’s Hilbert space now with the
same space later.
4. Convex combinations of Hamiltonian evolutions are essentially
unique (up to degeneracies).
Why should you (I) care?
If you do care, how can this be made convincing?
Status of quantum operations?
Effective attributes and effective Hamiltonians? “Effective reality”?
Kookaburras in New Mexico